Optical recognition system for capsules for the production of hot beverages

ABSTRACT

A method for the optical recognition of capsules for hot beverages machines comprises the steps of introducing a capsule in a machine, stimulating the capsule by an exciting optical signal emitted by a light source, reading a feedback optical signal by an optical reader, acquisition of the values of the frequency and/or the time frame of the feedback optical signal, determining the fulfillment of predetermined conditions on the values of the frequency and/or the time frame. On the basis of the step of evaluating there is then a step of blocking the normal operation of the machine or a step of pursuing the normal operation of the machine.

FIELD OF THE INVENTION

The present invention relates to the field of hot beverage production by means of capsule.

In particular, the invention relates to a method for recognizing capsules inserted in a machine for making such beverages.

DESCRIPTION OF THE PRIOR ART

As well known, over the last few years domestic production of coffee and other hot drinks has spread by means of capsules to be inserted into machines with special housings.

As is well known, machine makers relying on these systems need to make sure that the capsules to be inserted into their machines are suitable and meet predetermined quality requirements.

In fact, the use of capsules that do not meet the required standards may vary unexpectedly the organoleptic properties of the finished product and may generate potential toxicity due to substances or slags released from the plastic material of which the capsules are generally composed. Also, the operation of the machine itself may be damaged, or at least it may be wearier than what the machine manufacturer predicts, thus invalidating the sales warranty.

Clearly, these issues negatively affect both the image of the machine maker both, above all, the consumer's use of the product.

Therefore, in the prior art, markers have been proposed in order to identify suitable products.

However, in the case of marking with a center point or an outer ring it is extremely easy for anyone to fool the system by marking a non-original capsule with a suitable fluorescent or phosphorescent marker.

To mitigate this risk, more sophisticated systems with more complex markings have been conceived: for example, multiple concentric rings or barcodes.

However, these systems are also easy to bypass by using a stamp or a marker with a template. Furthermore, it becomes unavoidable to use both lighting and reading systems proportionally more complex and expensive, up to reaching the need, as in the case of barcodes, of proper image sensors that also need software and processors that increase further the cost of the system, up to make it unusable on the easiest and cheapest machines, which are the largest market segment and the one of more interest.

All these optical systems have then a strong vulnerability to splashes and dirty that inevitably accumulate in the reading area.

US2016325923A1 discloses a capsule for making drinks comprising a body with a base and a closure. Between the base and the upper closure it is arranged an identifier detectable by the machine where the capsule is inserted.

The problem of this type of control of the product is that the identifier is located outside the capsule. This causes a plurality of drawbacks. First of all, the identifier may also be illicitly applied on unsuitable capsules according to the standards imposed by the manufacturer. In addition, being exposed to the outside, the identifier may be accidentally removed, dirtied, or damaged before the capsule is inserted into the machine, causing problems also on suitable capsules.

SUMMARY OF THE INVENTION

It is therefore a feature of the present invention to provide a method for the optical recognition of capsules for hot beverages machines that is effective and not easy to bypass.

It is also a feature of the present invention to provide such a method that is not expensive and that can be easily installed also on already designed machines.

It is also a feature of the present invention to provide such a method that allows to recognize different types of capsules so that the type of beverage production can be varied based on the specific capsule inserted.

These and other objects are achieved by a method for optical recognition of capsules for hot beverages machines comprising the steps of:

-   -   marking the capsule with a recognition substance, said         recognition substance arranged to emit an optical signal at a         predetermined frequency B for a predetermined time frame K in         response to an excitation by an optical signal at a         predetermined frequency A and for a predetermined time frame H;     -   introducing the capsule in a hot beverages machine;     -   stimulating the capsule by an exciting optical signal emitted by         a light source of the machine, said exciting optical signal         being emitted at a predetermined frequency f₁=A and for a         predetermined time frame t₁=H;     -   reading a feedback optical signal by an optical reader of the         machine, said feedback optical signal being emitted by the         capsule at a frequency f₂ and for a time frame t₂;     -   acquiring the values of the frequency f₂ and/or the time frame         t₂ of the feedback optical signal;     -   evaluating the fulfillment of predetermined conditions on the         values of the frequency f₂ and/or the time frame t₂, said step         of evaluating being carried out by a control unit of the hot         beverages machine;     -   blocking the normal operation of the hot beverages machine in         case that the step of evaluating is negative;     -   pursuing the normal operation of the hot beverages machine in         case that the step of evaluating is positive;     -   whose main feature is that the recognition substance is located         inside the capsule.

Advantageously, a step is also provided of piercing the capsule in order to carry out the steps of stimulating and reading.

Advantageously, a production step of the capsule is provided, said step comprising the steps of:

-   -   prearranging a main body of the capsule;     -   filling the main body with a predetermined food substance, for         example coffee;     -   introducing the recognition substance, by means of a permeable         support element, for example a perforated disc, in the main         body;     -   sealing the main body (110) by a sealing film.

In particular, the recognition substance can be applied by molding on the permeable support element located above the substance food.

Alternatively, the recognition substance can be inserted directly in the material of which the permeable support element is made.

In an exemplary embodiment, the sealing film and/or the main body comprises at least one portion transparent to the optical signal emitted during the step of stimulating and to the feedback optical signal emitted during the step of reading.

This way, the upper film of the capsule can allow reading and checking the recognition substance, not allowing at the same time the accessibility to the recognition substance unless the capsule is tampered with.

This way, therefore, it is possible to mark the capsule with a recognition substance which allows the process of optical recognition above described both to recognize capsules unsuitable for machine operation both to recognize the specific capsule inserted.

Apart from being very versatile, the method described is also economical and easily implemented on machines that have already been designed.

In particular, the step of piercing is made by a perforation unit comprising at least one light guide.

Advantageously, the steps of stimulating and reading can be made through the punch pin arranged to pierce the capsule for injecting pressurized hot water in the production process of the hot beverage in the machine.

Advantageously, the step of evaluating is positive if it occurs the condition f₂≅B. In this case, the capsule is considered suitable if the frequency of the feedback optical signal is the one expected.

Alternatively, or in combination, the step of evaluating is positive if it occurs the condition t₂≅K. In this case, instead, the capsule is considered suitable if the time for transmitting the feedback optical signal is the one expected.

Advantageously, different conditions for the evaluation phase can be established, depending on the type of assessment you want to make. For example, you can change the range of acceptability of the frequencies at stake so you can determine the degree of accuracy of the selection.

In particular, a step is also provided of recognizing the capsule wherein the control unit detects a plurality of features of the capsule on the basis of the step of acquiring the values of the frequency f₂ and/or of the time frame t₂ of the feedback optical signal.

The conditions that cause the step of evaluating the suitability of the capsule can then be both on the frequency both on the time for transmitting the signal, or on a combination thereof, allowing generating a plurality of reference conditions that allow to extract by the capsule many information and not only the basics information on the suitability of the capsule.

For example, it is possible to detect the particular aroma contained in the capsule and to set the production process for the hot beverage on the basis of this information.

Advantageously, the frequencies f₁ and f₂ are different from each other and belong alternatively:

-   -   to the visible range;     -   to the UV range;     -   to the infrared range.

In particular, the frequency f₁ belongs to the UV range and the frequency f₂ belongs to the visible range. This can be obtained, for example, using as recognition substance a substance with fluorescent or phosphorescent features. In this case it is also possible to use the time for transmitting the feedback optical signal for access to many information about the content of the capsule.

According to another aspect of the invention, a system for recognizing capsules for hot beverages machines comprises:

-   -   a hot beverages machine comprising:         -   a light source arranged to emit an exciting optical signal             at a predetermined frequency and for a predetermined time             frame t₁=H;         -   an optical reader arranged to read a feedback optical signal             emitted at a frequency f₂ and for a time frame t₂;     -   a capsule arranged to be inserted in the machine;     -   said hot beverages machine arranged to emit the exciting optical         signal towards the capsule and to read the feedback optical         signal,     -   the main feature of the system being that the machine comprises         a control unit arranged to block the normal operation of the         machine in case that the values of the frequency f₂ and/or the         time frame t₂ do not meet predetermined conditions.

According to another aspect of the invention, a capsule for hot beverages machines is marked with a recognition substance, said recognition substance arranged to emit an optical signal at a predetermined frequency B for a predetermined time frame K in response to an excitation by an optical signal at a predetermined frequency A and for a predetermined time frame H.

BRIEF DESCRIPTION OF THE DRAWINGS

Further characteristic and/or advantages of the present invention are more bright with the following description of an exemplary embodiment thereof, exemplifying but not limitative, with reference to the attached drawings in which:

FIG. 1 shows a diagrammatical view of the method for the optical recognition of capsules, according to the present invention;

FIG. 2A diagrammatically shows the step of stimulating the capsule operated by a dichroic mirror;

FIG. 2B diagrammatically shows the step of reading the feedback optical signal operated by a dichroic mirror;

FIG. 3A shows, in cross section, a first exemplary embodiment of the step of piercing the capsule inside marked;

FIG. 3B shows, in cross section, a second exemplary embodiment of the step of piercing the capsule inside marked;

FIG. 3C shows, in cross section, a third exemplary embodiment of the step of piercing the capsule inside marked;

FIG. 3D shows, in cross section, a fourth exemplary embodiment of the step of piercing the capsule inside marked;

FIG. 4 shows, in cross section, an exemplary embodiment of the steps of stimulation and reading that provides a capsule having a transparent sealing film;

FIG. 5 graphically shows the trend with time of the exciting optical signals and of the feedback optical signal using two different recognition substances.

DESCRIPTION OF A PREFERRED EXEMPLARY EMBODIMENT

In FIG. 1 a diagrammatical scheme 300 is shown that describes, according to the present invention, a possible embodiment of the steps of the method for the optical recognition of capsules 100 for hot beverages machines.

After a first step of introducing the capsule 100 in the machine [301], there is a step of stimulating the capsule 100, wherein a light source 210 emits an optical signal with a predetermined frequency f₁≅A and for a predetermined time frame t₁≅H [302].

If the capsule 100 is remarkable with the predetermined recognition substance, it will respond to the optical signal received emitting a feedback optical signal at a frequency f₂≅B for a time frame t₂≅K.

In a preferred embodiment, the recognition substance has fluorescence properties, i.e. capable of re-transmitting an optical signal consisting of visible frequencies when it is excited with an optical signal having frequencies in the ultraviolet range.

In this exemplary embodiment, with reference even at FIGS. 2A and 2B, the machine has a dichroic mirror 230 arranged to result transparent to the optical frequencies of the visible range (black arrows) and to reflect the optical frequencies of the UV range (white arrows). This way, it is possible to use also low cost light sources 210, which normally emit light signals that in addition to the required frequencies UV contain also some unwanted visible frequencies. In this case, when the light source 210 will emit an optical bright signal comprising both visible and UV frequencies, only the UV ones are reflected towards the capsule 100, causing excitation.

The feedback optical signal is a signal comprising both the predetermined visible frequencies and the UV frequencies reflected and not converted by the recognition substance.

With reference to FIG. 2B, again the mirror dichroic 230 is transparent to the visible frequencies and it will reflect the UV frequencies, sending back them towards the source 210. Only the visible frequencies will then arrive to an optical reader 220 that will initiate a step of reading the signal itself [303]. The fact that the parasite UV frequencies are removed by the feedback optical signal ensures to the optical reader 220 a reading enough accurate also in case that you use a low cost reader.

The source 210 and/or the optical reader 220 need not necessarily to be located near the capsule 100. The exciting and feedback optical signals can be transported by respective optical fibers or, advantageously, by a single optical fiber used in both the directions.

In another preferred exemplary embodiment, the recognition substance has phosphorescent properties, and it is therefore arranged to send back a feedback optical signal that extends in time after the turning off of the exciting optical signal, normally for several millisecond. In this case, the optical reader 220 can start the step of reading the feedback optical signal only after that the exciting signal has been interrupted, avoiding interferences of unwanted reflected frequencies, without the need of using the dichroic mirror. Such exemplary embodiment is therefore cheaper than the previous.

After a step of acquiring the values of the frequency f₂ and of the time frame t₂ of the feedback optical signal [304], a control unit starts a step of evaluating the fulfillment of predetermined conditions on such values [305]. If the capsule 100 was a capsule correctly marked, the values of f₂ and t₂ will satisfy the above described conditions, allowing the machine to proceed with its correct operation. Otherwise, the machine will be blocked, avoiding the production of the hot beverage.

For example, in an exemplary embodiment previously described, where it is used a recognition substance with phosphorescent properties, the control unit can evaluate the law with which there is the decay with time of the feedback optical signal and test if the decay time respects or not predetermined conditions. Such procedure can allow then to transmit a large number of information by appropriately changing the recognition substance and then the decay time of the feedback optical signal. In this case, the frequency of the exciting signal f₁ can coincide with the frequency f₂ of the feedback signal.

In FIG. 4 is graphically shown the typical trend with time of the exciting and feedback optical signals. In particular, given a step exciting signal having a time frame t₁, can be to seen as two different substances A and B emit a feedback signals with different time frames t_(2A) and t_(22B). Such, as above said, allows distinguishing the substances to each other.

In the FIGS. 3A, 3B, 3C and 3D, are shown some possible exemplary embodiments of the step of piercing the capsule 100 for carrying out the steps of stimulating and reading.

In the FIGS. 3A and 3B the unit that provides to the steps of stimulating and reading the substance located within the capsule 100 implements even the perforation of the capsule, regardless of the perforator, not shown and located in another desired point, arranged to introduce pressurized hot water in the production process for the hot beverage.

In the FIGS. 3C and 3D the unit that provides to the steps of stimulating and reading the substance located within the capsule is instead housed inside of the same perforator 255 arranged to introduce pressurized hot water in the production process for the hot beverage.

For mere exemplifying purposes, the recognition substance located inside has a ring shape in FIGS. 3A and 3B and a point-shaped shape in FIGS. 3C and 3D.

In particular, in FIG. 3A the perforation unit 250 comprises two separate light guides 251, consisting of two glass or plastic perforating rods, in optical connection with the relative components located at short distances.

In FIG. 3B the perforation unit 250 comprises instead a single light guide 251 comprising a single glass or plastic perforating rod, in optical connection with the respective lighting/reading components, thanks to a suitable splitter of the two signals.

In FIG. 3C the perforation unit 250 comprises two separate light guides 251, housed within the punch pin 255 arranged to introduce the hot water, which allow to house the components of lighting/reading on the main electronic board, which is located in remote.

In FIG. 3D the perforation unit 250 comprises a single optical fiber 251, housed within the punch pin 255 arranged to introduce the hot water, and a suitable splitter of the 2 signals mounted on the main electronic board, which is located in remote.

In FIG. 4 the capsule 100 comprises a film 130 having at least one transparent portion. In this exemplary embodiment, the steps of stimulating and reading the inner marker are made through the light source 210 and the optical reader 220, without needing to perforate the film 130 itself.

In this exemplary embodiment, the light source 210 and the optical reader 220 can be separated by a barrier 215 arranged to be placed in contact with the transparent portion 130′ in order to prevent that, in case of introducing a not suitable capsule having an illicit recognition substance located on the outer surface of the film 130, the feedback optical signal can reach the optical reader 220.

The foregoing description some exemplary specific embodiments will so fully reveal the invention according to the conceptual point of view, so that others, by applying current knowledge, will be able to modify and/or adapt in various applications the specific exemplary embodiments without further research and without parting from the invention, and, accordingly, it is meant that such adaptations and modifications will have to be considered as equivalent to the specific embodiments. The means and the materials to realize the different functions described herein could have a different nature without, for this reason, departing from the field of the invention. It is to be understood that the phraseology or terminology that is employed herein is for the purpose of description and not of limitation. 

1. A method for the optical recognition of capsules for hot beverages machines comprising the steps of: marking a capsule with a recognition substance, said recognition substance arranged to emit an optical signal at a predetermined frequency B for a predetermined time frame K in response to an excitation by an optical signal at a predetermined frequency A and for a predetermined time frame H; introducing said capsule in a hot beverages machine; stimulating said capsule by an exciting optical signal emitted by a light source of said machine, said exciting optical signal being emitted at a predetermined frequency f₁=A and for a predetermined time frame t₁=H; reading a feedback optical signal by an optical reader of said machine, said feedback optical signal being emitted by said capsule at a frequency f₂ and for a time frame t₂; acquiring the values of said frequency f₂ and/or of said time frame t₂ of said feedback optical signal; evaluating the fulfillment of predetermined conditions on said values of said frequency f₂ and/or of said time frame t₂, said step of evaluating being carried out by a control unit of said hot beverages machine; blocking the normal operation of said hot beverages machine in case that said step of evaluating is negative; pursuing the normal operation of said hot beverages machine in case that said step of evaluating is positive; said method characterized in that said recognition substance is located inside said capsule (100).
 2. The method for the optical recognition of capsules, according to claim 1, wherein a step is also provided of piercing said capsule in order to carry out said steps of stimulating and reading.
 3. The method for the optical recognition of capsules, according to claim 2, wherein said step of piercing is made by a perforation unit comprising at least one light guide.
 4. The method for the optical recognition of capsules, according to claim 1, wherein a production step of said capsule is provided, said step comprising the steps of: prearranging a main body of said capsule; filling said main body with a predetermined food substance; introducing said recognition substance, by means of a permeable support element, in said main body; sealing said main body by means of a sealing film.
 5. The method for the optical recognition of capsules, according to claim 4, wherein said sealing film and/or said main body comprises at least one portion transparent to said exciting optical signal emitted during said step of stimulating and to said feedback optical signal emitted during said step of reading.
 6. The method for the optical recognition of capsules, according to claim 1, wherein said step of evaluating is positive if it occurs the condition f₂≅B.
 7. The method for optical recognition of capsules, according to claim 1, wherein said step of evaluating is positive if it occurs the condition t₂≅K.
 8. The method for the optical recognition of capsules, according to claim 1, where a step of recognizing said capsule is provided wherein said control unit detects a plurality of features of said capsule on the basis of said step of acquiring said values of said frequency f₂ and/or of said time frame t₂ of said feedback optical signal.
 9. The method for the optical recognition of capsules, according to claim 1, wherein said frequencies f₁ and f₂ are different from each other and belong alternatively: to the visible range; to the UV range; to the infrared range.
 10. The method for the optical recognition of capsules, according to claim 1, wherein said frequency f₁ belongs to the UV range and said frequency f₂ belongs to the visible range.
 11. A system for recognizing capsules for hot beverages machines, said system comprising: a hot beverages machine comprising: a light source arranged to emit an exciting optical signal at a predetermined frequency f₁≅2 A and for a predetermined time frame t₁≅H; an optical reader arranged to read a feedback optical signal emitted at a frequency f₂ and for a time frame t₂; a capsule configured to be inserted in said machine; said hot beverages machine arranged to emit said exciting optical signal towards said capsule and to read said feedback optical signal, said system characterized in that said hot beverages machine comprises a control unit arranged to block the normal operation of said hot beverages machine in case that the values of said frequency f₂ and/or of said time frame t₂ do not meet predetermined conditions.
 12. A capsule for hot beverages machines, said capsule being marked internally with a recognition substance, said recognition substance arranged to emit an optical signal at a predetermined frequency B for a predetermined time frame K in response to an excitation by an optical signal at a predetermined frequency A and for a predetermined time frame H.
 13. The capsule for hot beverages machines, according to claim 12, wherein said capsule comprises at least one transparent portion arranged to allow said emission by said recognition substance of said optical signal at said predetermined frequency B for said predetermined time frame K in response to said excitation by said optical signal at said predetermined frequency A and for said predetermined time frame H.
 14. The method for the optical recognition of capsules, according to claim 2, wherein said step of evaluating is positive if it occurs the condition f₂≅B.
 15. The method for optical recognition of capsules, according to claim 2, wherein said step of evaluating is positive if it occurs the condition t₂=K.
 16. The method for the optical recognition of capsules, according to claim 2, where a step of recognizing said capsule is provided wherein said control unit detects a plurality of features of said capsule on the basis of said step of acquiring said values of said frequency f₂ and/or of said time frame t₂ of said feedback optical signal.
 17. The method for the optical recognition of capsules, according to claim 2, wherein said frequencies f_(t) and f₂ are different from each other and belong alternatively: to the visible range; to the UV range; to the infrared range.
 18. The method for the optical recognition of capsules, according to claim 2, wherein said frequency f₁ belongs to the UV range and said frequency f₂ belongs to the visible range. 